Multi-point tension distribution system device and method of tissue approximation using that device to improve wound healing

ABSTRACT

A tissue approximation device and processes for using the device are provided. The device is an implantable, biodegradable construct (except for hernia repairs) that has attachment points emanating from a supportive backing. The device improves the mechanical phase of wound healing and evenly distributes tension over the contact area between the device and tissue. Processes for using the device include wound closure, vascular anastomoses, soft tissue attachment and soft tissue to bone attachment.

FIELD OF THE INVENTION

This invention is in the field of surgery. More particularly, it relates to a tissue approximation device that facilitates wound healing by holding soft tissue together under improved distribution of tension and with minimal disruption of the wound interface and its nutrient supplies. The device has multiple sites for grasping said tissue using tines or prongs or other generally sharp, projecting points, extending from a single, supportive backing. Various processes of using the inventive device are also a portion of the invention.

BACKGROUND OF THE INVENTION

The surgically induced healing of soft tissue wounds involves two phases, the mechanical phase of wound closure followed by the biochemical phase which involves protein bridging and scarring. In the mechanical phase, the edges of soft tissue are held in contact by essentially two components: 1) The physical properties and device-tissue interactions of the materials holding the tissue edges in contact, e.g. sutures or staples; and 2) An early deposition of proteinaceous material that has adhesive characteristics, e.g. fibrin glue.

Only in the biochemical phase, which occurs after the mechanical phase, do tissue components replace the mechanical components adhering the wound surfaces. During the biochemical phase, the inflammatory cascade generates signals which induce fibroblasts to migrate into the wound and synthesize collagen fibers.

Collagen is the primary constituent of connective tissue and ultimately determines the pliability and tensile strength of the healing wound. Tensile strength is gradually recovered; 60% of ultimate wound strength is achieved after approximately 3 months. However, this process is successful only if the previous mechanical phase has proceeded normally.

The surgeon's goal is to optimize the strength and often the cosmetic appearance of a wound closure or tissue coaptation. For this to happen, tissue is mechanically approximated until the wound has healed enough to withstand stress without artificial support. Optimal healing requires the application of appropriate tissue tension on the closure to eliminate dead space but not create ischemia within the tissue. Both of these circumstances increase the risk of wound infection and wound dehiscence.

Although the biomaterial composition of sutures has progressed considerably, the sophistication of manual suture placement in wounds has advanced relatively little since the original use of fabrics several thousand years ago to tie wound edges together. The wide tolerance ranges for suture placement, tension, and configurations, both amongst different surgeons and for different implementations by the same surgeon, result in a significant component of sub-optimal technique. Yet, the technique used for wound closure forms the foundation for all subsequent events in the healing process. It is during this mechanical phase that tissue tension is high, edema and inflammation are intense, wound edge ischemia is greatest, and that one can already observe the complication of wound failure.

Soft tissue is well known for its inability to hold tension. Even when optimally placed, sutures gradually tear through soft tissue, producing gaps in wounds and possibly leading to the eventual failure or sub-optimization of wound healing. Furthermore, since sutures require the implementation of high levels of tension to counteract the forces acting to separate tissues, they may strangulate the blood supply of the tissues through which they are placed, thus inhibiting the delivery of wound nutrients and oxygen necessary for healing.

There have been many attempts to construct wound closure devices that decrease closure time and improve cosmesis. U.S. Pat. Nos. 2,421,193 and 2,472,009 to Gardner; U.S. Pat. No. 4,430,998 to Harvey et al.; U.S. Pat. No. 4,535,772 to Sheehan; U.S. Pat. No. 4,865,026 to Barrett; U.S. Pat. No. 5,179,964 to Cook; and U.S. Pat. No. 5,531,760 to Alwafaie suggest such devices. However, these devices are not useful in surgical or deeper wounds. They only approximate the skin surface, joining skin edges variously through external approaches, using adhesives or nonabsorbable attachment points that penetrate tissue. The devices minimally improve the biomechanics of wound closure, and do not adequately approximate the deeper layers of the closure, i.e. fascia or dermis. Externally placed attachment points that puncture the skin lateral to the wound also interfere with long-term cosmesis and provide a possible conduit for infecting micro-organisms.

U.S. Pat. No. 5,176,692 to Wilk et al., discloses a device for hernia repair that utilizes mesh with pin-like projections to cover hernia defects. This device, however, is used in a laparoscopic hernia repair in conjunction with an inflatable balloon. Closure devices for deeper tissues are described in U.S. Pat. No. 4,610,250 to Green; U.S. Pat. No. 5,584,859 to Brozt et al.; and U.S. Pat. No. 4,259,959 to Walker. However, these devices either work in conjunction with sutures, are made of materials that do not suggest biodegradability, or are designed in such a way as not to impart uniform tension on the closure, increasing the risk of wound separation and failure of wound healing.

The present invention is a biodegradable tissue approximation device. The device includes a plurality of attachment points, e.g. tines, prongs, or other generally sharp or blunt parts, connected to a backing that can be manipulated to close wounds, join soft tissue or bone, or create anastomoses. This multi-point tension distribution system (MTDS) device may be placed with minimal tissue trauma. The present invention typically incorporates the deeper layers of tissue within the closure, and the multiple attachment points distribute the resulting tension, often uniformly. Approximation from the internal aspect of the wound minimizes the potential for dead space in the closure, thus decreasing the risk of sub-optimal healing. Moreover, because the device is absorbed, a second procedure is not typically needed to remove the device.

Thus, the present invention improves the mechanical phase of healing by facilitating wound closure and/or the coaptation of tissues prior to initiation of the biochemical phase of wound healing. Placement of the device maximizes the chance for a good cosmetic result and is not heavily dependent on surgeon skill. Closure time is also shortened, decreasing overall cost and risk of operative complications.

SUMMARY OF THE INVENTION

The present invention is a device that improves the mechanical phase of wound healing. In the preferred embodiment, tissue edges are stabilized by a plurality of attachment points that extend from a supportive backing. The density, shape, length, and orientation of attachment points on the backing may be varied to suit the procedure, type of tissue being approximated, and/or area of the body involved. The flexibility of the backing is also variable and dependent on the materials used and dimensions of the backing. In the preferred embodiment, the device is biodegradable, and the attachment points uniformly distribute tension over the contact area between the device and tissue.

Processes of using the present invention are also provided. The device may be used to close wounds and create vascular anastomoses. The device may also be manipulated to approximate soft tissue and soft tissue to bone.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A-1D are plan, perspective views of various MTDS devices.

FIGS. 2A-2E are side views of various attachment point shapes and orientations.

FIGS. 3A-3D and 3F-3G are side views of various attachment points.

FIG. 3E is a side view of a two-sided MTDS device.

FIG. 3H is a plan, reverse perspective view of nubs on the inferior surface of a MTDS device.

FIG. 4A is a side, cross-sectional view of attachment points that run through the width of a backing.

FIG. 4B is a side view of attachment points on a strip of backing material.

FIG. 4C is a plan, perspective view of the embodiment in 4B on a backing.

FIG. 4D is a plan, perspective view of attachment points on a solid backing.

FIG. 5A is a plan, perspective view of attachment points canted in one direction.

FIGS. 5B-5D are plan, perspective views of attachment points with various orientations on a backing.

FIG. 5E is a side view of attachment points becoming progressively shorter the closer they are to the center of the device.

FIG. 5F is a side view of attachment points becoming progressively shorter the farther they are from the center of the device.

FIGS. 6A-6B are schematic views of a skin wound and wound repair using the MTDS device.

FIG. 7 is a schematic view of an abdominal wound closure using MTDS devices.

FIGS. 8A-8B are schematic views of an abdominal hernia and hernia repair using the MTDS device.

FIGS. 8C-8D are side and schematic views, respectively, of a MTDS device with attachment points on the edges of the backing and a central area without attachment points.

FIGS. 9A-9B are schematic views of a ruptured tendon and tendon to bone repair using the MTDS device.

FIG. 10A is an axial view of a cross-section of a vessel repaired with the MTDS device.

FIGS. 10B-10C are side, schematic views of vessel free ends and a vascular anastomosis using the MTDS device.

FIGS. 11A and 11B-11C are schematic, side, and cross-sectional side views, respectively, of a transected tendon and a tendon to tendon repair using the MTDS device.

FIG. 11D is an axial, cross-sectional view of the MTDS tendon to tendon repair.

FIG. 11E is a side view of a vascular anastomosis using the MTDS device on the external surface of a vessel.

FIGS. 11F-11G are side, schematic views, and FIG. 11H is an axial view of the ends of a tubular structure being joined by externally placing strips of a MTDS device on approximated tissue.

FIG. 11I is an axial view of a hinge in the backing of a device.

FIGS. 11J-11K are axial views of decreased backing material that are areas of enhanced device flexibility.

FIGS. 11L-11M are side views of a spring or coil-like MTDS device being used to approximate tissue.

FIG. 12A is a schematic view of the MTDS device being used in a brow-lift procedure.

FIG. 12B is a plan, perspective view of the MTDS device used in a brow-lift.

DETAILED DESCRIPTION

Our inventive device may be used when working with bone anchors or a variety of soft tissues. The device is of the general configurations shown in FIGS. 1A-1B and comprises a plurality of attachment points (102) emanating from a supportive backing (100) that is a generally a porous material that may have the structure of a mesh, net, or lattice. The degree of flexibility of the backing is determined by the material of construction, the shape and dimensions of the device, the type and properties of the approximated tissue, and the area of the body into which the device is placed. For example, a tightly curved or mobile part of the body, e.g. a joint, will require a more flexible backing, as would a tendon or nerve repair due to the amount of bending the device needs for the attachment. Also, depending on the type of material used, the thickness of the backing as well as its width and length may determine the flexibility of the device. Furthermore, the backing may be pre-fabricated into different shapes as shown by the sharp corners (104) and rounded corners (106) in FIGS. 1C and 1D. The fabricated cross-sectional shape and dimensions of the mesh elements may vary to promote flexibility in regions of the backing. The cross-sectional shape of the mesh elements may be chosen to minimize local compressive stress between the backing and surface it rests upon, or have rounded and filleted edges to be less obtrusive to local circulation. The plurality of attachment points distribute tension over the contact area between the device and the tissue.

Materials such as biodegradable polymers are preferably used to construct the backing and attachment points. Polymers synthesized from monomers comprising esters, anhydrides, orthoesters, and amides are particularly suitable for biodegradation. Examples of biodegradable polymers are polyglycolide, polylactide, poly-α-caprolactone, polydiaxanone, polyglyconate, polylactide-co-glycolide, and block and random copolymers of these polymers. Copolymers of glycolic, lactic, and other α-hydroxy acids are highly desirable. Although we prefer to use a single polymer or copolymer in a specific device, generally for ease of construction, the invention is not so limited. An example of an inventive device may be made of two or more types of polymers or copolymers (or molecular weights of the same polymer or copolymer). For instance, the backing material might be produced from a more flexible polymer and the points or tines of a stiffer material. The inflammatory response to these polymers is minimal, and they have been safely used in suture materials, stents, drug delivery devices, orthopedic fixation devices, and intestinal anastomotic rings.

Generally, we will refer to the attachment points as “tines” or “prongs”. These tines will refer both to points which are either sharp, i.e. able to separate tissue in a chosen use, or blunt, i.e. not able to separate tissue in that use. The attachment points may also be referred to as “barbs” when those points have the retaining point shown in several of the Figures discussed below.

As shown in FIGS. 2A-2E, the shape of the attachment points or barbs may be varied depending, e.g., on the area of the body involved and the type of tissue requiring closure or reapproximation. The tines may be canted or erect, but in a preferred variation, the general structure of the tines is of a rose thorn shape. The tines (200) have a wide base (202) that supports a projection (204) from the backing (206) against the degree of tension required to close a wound or approximate tissue. For example, the attachment points may be erect tine (FIG. 2B-208), canted tine (FIG. 2C-210), canted arrowhead (FIG. 2D-212), canted hook (FIG. 2E-214), or may have a single straight cross-section (FIG. 3G-311) that is nail-like, that does not vary over the length of the prong, for example, similar in shape to a nail or sharpened pencil. Furthermore, the tip of the attachment points may be varied as shown in FIGS. 3A-3D. The tips may be barbed (300), arrowhead (double-barb) (302), or cheese grater (304). A side view of the cheese grater tips is shown in FIG. 3D.

The connection of the prong to the backing may be rounded or filleted, or the backing built-up around the prong, to reduce structural stress concentrations. The backing or connecting structure may branch out away from the center, with each branch in turn branching to grapple tissue in a distributed fashion. All edges of the device may be smooth except where sharpness is needed at the tip of the prong to pierce into the tissue. Once the prongs pierce into the tissue, the tissue may become supported against the backing to minimize additional piercing or irritation by the prong tip. The device may be molded, stamped, machined, woven, bent, welded or otherwise fabricated to create the desired features and functional properties.

The MTDS device may also have attachment points both on its front side (305) and on a back side (307). As shown in FIGS. 3B and 3E, the front and back sides have attachment points. The attachment points on the front side (309) generally approximate tissue. The attachment points on the back side (307) are auxiliary attachment points that may comprise forms such as round nubs (306) or pointed nubs (308). The auxiliary attachment points may be used to secure or promote stable implantation of the device. Soft tissue may be gently pressed into open regions of the backing thereby helping to fix the device in place against both underlying and overlying tissue. FIG. 3H shows a reverse view of the nubs (310) on the back side of the device (312). The attachment points on a two-sided device are not limited to the combinations disclosed above, but may comprise any combination of the previously mentioned attachment point shapes and orientations.

Structural variations can also be made to the backing of the device. As shown in FIG. 4A, the attachment points (400) may be placed through a plurality of openings in the backing (402) and secured to the backing by a flange (404) or hub. In FIGS. 4B and 4C, the points (406) may also connect to strips (408) of the same material as the attachment points which are then secured to a backing (410). The backing may also be comprised of a solid material (412) instead of a porous material.

The extent of porosity, or total surface area may be used to control the absorption rate of the device, and may also be used to optimize the strength-to-mass properties of the device, increasing the section modulus of structural cross-sections per unit mass. The backing structure may comprise partial folds, waves or grooves to help hold tissue against both surfaces of the backing. Regions of the backing may function as suction cups to help hold tissue to the backing.

The density, distribution, length, and orientation of attachment points on the backing may be modified depending on the type of wound closure. Attachment points may be bent or curve gradually, with the tip directed at an optimal angle relative to the backing to aid device penetration and stability within the tissue, and to reduce tissue irritation after device installation. Attachment points may be canted in one direction (500), such as toward the center of the device as shown in FIG. 5A. The attachment points may also be variously oriented, such as toward center (502) and erect (504), or toward center (502) and away from center (506). It is within the scope of this invention to have attachment points extending in any relative direction or orientation on the backing. Or, as shown in FIG. 5D, the backing is divided into a first area (508) and a second area (510). Attachment points in the first area (512) and second area (514) are canted toward each other. The inventive device may also be sectioned into a plurality of areas, with each section being variously oriented to another section.

In another variation of the invention, attachment points of various lengths emanate from a single backing. For example, in FIG. 5E, the attachment points (515) are progressively shorter the closer they are to the center of the device (516). The attachment points (515) may also become progressively shorter the farther they are from the center of the device as shown in FIG. 5F. The variations shown in FIGS. 5B and 5C have regions of attachment points canted toward the center (502) and with other regions of attachment points with erect points (504 in FIG. 5B) or canted away from the other end (506 in FIG. 5C) of the device. These variations are more difficult to dislodge when situated in an area of the body having both to-and-fro movement, e.g., the inside of an elbow or back of the knee, or during placement of the device.

Portions of simple wound closures are shown in FIGS. 6A-6B. These wound closures involve placing the MTDS device (600) at the bottom of the wound, usually at the level of the sub-dermis (602). The edges of the wound (604) are approximated and then secured by fixation, e.g., by pressing, to the multiple attachment points (606). An example of the MTDS device placement in a laparotomy closure is shown in FIG. 7. The increased length of this incision requires placement of multiple devices (700).

A unique application of this device occurs in hernia repair in which case the biomaterials are not absorbable but rather are more likely to be PTFE and POPU (“Gore-Tex”), polypropylene, or other permanent implant material. Once the hernia (801) is reduced, a MTDS device may be used to close the hernia defect by joining the edges of the separated fascia (804) as seen in FIGS. 8A and 8B. However, the device may also be modified to aid repair of a difficult hernia resulting from such circumstances as operating on an obese patient or large hernia, or having a wide fascial debridement where the fascial edges cannot be brought together. FIGS. 8C and 8D are variations of the inventive device that may be used in these cases. The attachment points (800) are secured to the ends of the backing (806) and are still used to adhere the device to tissue, but the points are spaced so that the central area of the backing is a flat surface without points (802) that covers the defect. The device in FIG. 8D is preferably used in an incisional hernia repair.

The MTDS device may also be constructed to reattach soft tissue such as tendons and ligaments to bone, as well as other soft tissue such as cartilage and the free ends of vessels or nerves. In FIG. 9A, the inventive device functions similar to a clamp. Backings with attachment points (900) are sides of a clamp that has a first end (901) and a second end (904). The first end (901) grasps tissue and the second end (904) is an anchor for tissue. For example, a ruptured tendon (906) may be fixed to the attachment points (908) of the first end of the clamp (901) and approximated to bone (902) with an anchor such as a pin or nail at the second end of the clamp (904), as seen in FIG. 9B. After mechanical fixation of the tissues, the biochemical phase of the wound healing process will begin, eventually forming a natural union between tendon and bone. Ligament and cartilage to bone unions using the MTDS device would undergo the same mechanical and biochemical processes.

Vascular anastomoses may also be constructed with the MTDS device. In FIG. 10B, the backing has a tubular shape (1000) with attachment points (1001) on the outside surface (1002). The outside surface (1002) has a first end (1003) and a second end (1005) that opposes the first end (1003). The free ends of a vessel(s) (1004) are placed over the device, creating an anastomosis (1006) that is secured by attachment points fixed into the wall of the vessels (1008). The attachment points are preferably pointing towards the anastomosis (1006), with the attachment points on the first end (1003) being canted toward the second end (1005) and vice-versa. An axial view of the relationship of the attachment points (1010) to the vessel wall (1012) is shown in FIG. 10A.

Vessels and other soft tissue such as nerves, cartilage, tendons, and ligaments may also be joined as seen in FIGS. 11A and 11B. Two ends of tissue (1100) are brought and held together by the backing and attachment point construct (1102) being wrapped around the circumference of the tissue (1104). The attachment points (1106) are on the inside surface of the backing (1107) and secure the union at a central region (1108) as seen in FIG. 11C. An axial, cross-sectional view of the relationship between the attachment points (1110) and tissue (1112) is shown in FIG. 11D. The resulting form is, i.e., a tubular structure that has an inside surface (1107) with a central region (1108). The attachment points on the inside surface (1106) are canted toward the central region (1108). FIG. 11E shows the device with attachment points (1101) on the inside surface of the backing (1103) being wrapped around vessel ends to create an anastomosis (1105). Instead of being wrapped around tissue, edges (1113) of tubular structures (1115) can also be joined by externally placing 2 or more strips of backing of a MTDS device (1114) on approximated tissue as shown in the side views of FIGS. 11F-11G, and the axial view in FIG. 11H. The attachment points (1117) also point toward the area of tissue approximation (1116).

FIGS. 11I-11M are additional variations of the invention which vary the mechanisms used to improve device flexibility. In FIGS. 11I-11K, the backing has areas of comparatively higher flexibility than other areas of the backing. In an axial view of the variation in FIG. 11I, the backing is equipped with hinges (1118) that allow bending of the backing (1120) around tubular soft tissue structures (1115). In a second variation, the amount of material in the areas of the device that fold (1122) is reduced as shown in FIGS. 11J-11K. Another variation is seen in FIGS. 11L-11M where attachment points (1124) of a device extend from a backing in the form of a coil or spring (1126). The edges of soft tissue are approximated when the coil or spring is reduced (1128).

The MTDS device may also be used in soft-tissue remodeling, such as a brow-lift, shown in FIG. 12A. After dissection of the scalp (1200), the anterior scalp flap (1202) may be raised over the attachment points (1204) to lift the brow (1206). The ends of both the anterior flap (1202) and posterior flap (1208) may then be trimmed and fixed onto the attachment points (1204) to close the wound. The device may be secured to the skull (1210) by a screw (1212). The inventive device in this example may have a first end (1214) and a second end (1216), the first end having a first area (1215) and the second end having a second area (1217). The first area (1215) and second area (1217) may have extending attachment points (1204) or one or more openings (1218) to accommodate a screw(s) (1212). The second area attachment points are canted toward the first end of the device as shown in FIG. 12B.

We have described this invention by example and by description of the physical attributes and benefits of the structure. This manner of describing the invention should not, however, be taken as limiting the scope of the invention in any way. 

We claim:
 1. An implantable device for placement on a tissue surface and interior to an exterior tissue surface comprising; a) a biodegradable supportive backing having: i.) at least a first area with a plurality of biodegradable attachment points extending from the first area for attaching to a selected tissue and ii.) a second area discrete from the first area, wherein the backing has physical characteristics sufficient to approximate or to support the selected tissue adjacent the first area with respect to the second area, and b) the plurality of biodegradable attachment points extending from the first area, wherein the plurality of biodegradable attachment points are configured to attach to the selected tissue and to distribute tension between the first area and the selected tissue.
 2. The implantable device of claim 1 wherein said plurality of biodegradable attachment points comprise more than one shape.
 3. The implantable device of claim 1 wherein said plurality of biodegradable attachment points comprise shapes and directions selected from the group consisting of canted tines, erect tines, canted hooks, canted arrowheads, erect barbed tipped tines, canted barbed tipped tines, erect arrowhead tipped tines, canted arrowhead tipped tines, erect nail-shaped tines, canted nail-shaped tines, and cheese grater-like tines.
 4. The implantable device of claim 1 wherein said biodegradable supportive backing comprises front and back sides.
 5. The implantable device of claim 4 wherein said plurality of biodegradable attachment points extend from the biodegradable supportive backing on said front and back sides.
 6. The implantable device of claim 5 wherein auxiliary biodegradable attachment points extend from said back side.
 7. The tissue approximation device of claim 6 wherein said auxiliary attachment points have shapes and directions selected from the group consisting of canted tines, erect tines, canted hooks, canted arrowheads, erect barbed tipped tines, canted barbed tipped tines, erect arrowhead tipped tines, canted arrowhead tipped tines, erect nail-shaped tines, canted nail-shaped tines, and cheese grater-like tines.
 8. The implantable device of claim 6 wherein said auxiliary attachment points have shapes selected from the group consisting of rounded nubs and pointed nubs.
 9. The implantable device of claim 1 wherein said plurality of biodegradable attachment points extending from said backing are varied in density on said backing.
 10. The implantable device of claim 1 wherein said plurality of biodegradable attachment points extending from said backing are varied in length on said backing.
 11. The implantable device of claim 10 wherein biodegradable supportive bang also comprises a center and said plurality of biodegradable attachment points are progressively shorter the closer they are to the center of the backing.
 12. The implantable device of claim 1 wherein said plurality of biodegradable attachment points extending from the biodegradable supportive backing are varied in orientation on said backing.
 13. The implantable device of claim 1 wherein said biodegradable supportive backing comprises porous material.
 14. The implantable device of claim 13 wherein said porous material comprises a mesh, net, or lattice.
 15. The implantable device of claim 1 wherein said biodegradable supportive backing comprises a solid material.
 16. The implantable device of claim 1 wherein said biodegradable supportive backing comprises a plurality of open through which a plurality of biodegradable attachment points are placed.
 17. The implantable device of claim 16 wherein said plurality of biodegradable attachment points are secured to said biodegradable supportive backing by a flange or hub.
 18. The implantable device of claim 1 wherein said attachment points extend from strips of backing consisting essentially of the same material as said attachment points.
 19. The implantable device of claim 18 wherein said strips of backing are secured to a backing.
 20. The implantable device of claim 1 wherein said biodegradable supportive backing and said plurality of biodegradable attachment points comprise a polymer or copolymer.
 21. The implantable device of claim 20 wherein said polymer or copolymer comprises one or more materials selected from the group consisting of polyglycolide, polylactide, poly-α-caprolactone, polyglyconate, polylactide-co-glycolide, their mixtures, alloys, and random and block copolymers.
 22. The implantable device of claim 1 wherein said biodegradable supportive backing comprises opposing end areas and a central area located between said opposing end areas.
 23. The implantable device of claim 22 wherein said plurality of biodegradable attachment points are located in said opposing end areas.
 24. The implantable device of claim 23 wherein said central area is without attachment points.
 25. The implantable device of claim 1 first area having a plurality of biodegradable attachment points extending therefrom is situated at a first end of the biodegradable supportive backing and the second area is situated at an opposing end and has one or more openings through said biodegradable supportive backing.
 26. The implantable device of claim 25 wherein said first area plurality of biodegradable attachment points are canted toward said second end.
 27. The implantable device of claim 1 wherein said biodegradable supportive backing is tubular in shape and has an outside surface, an inside surface, a first end, and a second end opposing said first end.
 28. The implantable device of claim 27 wherein said outside surface comprises the first area with a plurality of biodegradable attachment points on said first end and said plurality of attachment points are canted toward said second end.
 29. The implantable device of claim 28 wherein said outside surface further comprises the second area located on said second end and the second area includes biodegradable attachment points extending therefrom and canted toward said first end.
 30. The implantable device of claim 1 wherein said biodegradable supportive backing is configured to be wrapped around tissue to form a tubular structure and has an inside surface with a central region.
 31. The implantable device of claim 30 wherein said inside surface comprises attachment points canted toward said central region.
 32. The implantable device of claim 1 wherein said biodegradable supportive backing comprises regions of comparatively higher flexibility than other regions of said biodegradable supportive backing.
 33. The implantable device of claim 32 wherein said regions of higher flexibility comprise hinges.
 34. The implantable device of claim 33 wherein said regions of higher flexibility comprise a reduced amount of backing material.
 35. The implantable device of claim 1 wherein said biodegradable supportive backing comprises sides of a clamp.
 36. The implantable device of claim 35 wherein said clamp comprises a first clamp end and a second clamp end.
 37. The implantable device of claim 36 wherein said-first clamp end grasp tissue and said second clamp end comprises an anchor for tissue.
 38. The implantable device of claim 37 wherein said anchor comprises a pin, nail, or screw.
 39. The implantable device of claim 1 wherein said biodegradable backing is in a helical form.
 40. The implantable device of claim 1 comprising an assembly of two or more strips comprising the biodegradable supportive backing attaching edges of tubular structures.
 41. An implantable tissue approximation device comprising: a) a biodegradable backing having i.) opposing first and second ends separated by a center area, ii.) discrete first and second contact areas respectively adjacent the opposing first and second ends, and iii.) a plurality of biodegradable attachment points extending both from the first and second discrete contact areas, wherein the plurality of biodegradable attachment points are configured to attach to tissues adjacent the first and second discrete contact areas, and wherein the biodegradable backing has physical characteristics sufficient to approximate tissue adjacent the first contact area with respect to the discrete second contact area, and b) the plurality of biodegradable attachment points extending both from the first and second discrete contact, wherein the plurality of biodegradable attachment points are configured to distribute tension between those first and second contact areas and the respective adjacent tissues, and wherein the plurality of biodegradable attachment points have shapes and directions selected from the group consisting of canted tines, erect tines, canted hooks, canted arrowheads, erect barbed tipped tines, canted barbed tipped tines, erect arrowhead tipped tines, canted arrowhead tipped tines, erect nail-shaped fines, canted nail-shaped tines, and cheese grater-like tines.
 42. The tissue approximation device of claim 41 wherein a majority of said plurality of biodegradable attachment points are canted toward said center area.
 43. The tissue approximation device of claim 41 wherein said plurality of biodegradable attachment points are canted toward said center area.
 44. The tissue approximation device of claim 41 wherein said biodegradable backing and said plurality of biodegradable attachment points comprise at least one biodegradable material selected from polymers and copolymers.
 45. The tissue approximation device of claim 41 wherein said biodegradable backing further comprises front and back sides and wherein said biodegradable backing has biodegradable attachment points on said front and back sides.
 46. The tissue approximation device of claim 45 wherein said back side comprises auxiliary attachment points.
 47. The tissue approximation device of claim 46 wherein said auxiliary attachment points have shapes and directions selected from the group consisting of canted tines, erect tines, canted hooks, canted arrowheads, erect barbed tipped tines, canted barbed tipped tines, erect arrowhead tipped tines, canted arrowhead tipped tines, erect nail-shaped tines, canted nail-shaped tines, and cheese grater-like tines.
 48. The tissue approximation device of claim 46 wherein said auxiliary attachment points have shapes selected from the group consisting of rounded nubs and pointed nubs.
 49. A method of distributing tension over an interior tissue surface and between said interior tissue surface and a backing on an implantable device comprising the steps of: a) identifying the interior tissue or layer of tissue over which said tension is to be distributed; and b) introducing the implantable device of claims 1 and 4-48 upon surface of said tissue over which the tension is to be distributed, whereby the tension is distributed over the selected interior tissue surface and between the implantable device backing and the selected interior tissue surface.
 50. The method of claim 49 wherein said tissue over which tension is to be distributed is adjacent a wound.
 51. The method of claim 48 wherein said tissue comprises soft tissue.
 52. The method of claim 49 wherein said tissue comprises soft tissue and bone.
 53. The method of claim 52 wherein said soft tissue comprises tendons.
 54. The method of claim 52 wherein said soft tissue comprises ligaments.
 55. The method of claim 49 wherein said tissue comprises vascular anastomoses.
 56. The method of claim 49 wherein said tissue comprises tendons.
 57. The method of claim 49 wherein said tissue comprises nerves.
 58. The method of claim 49 wherein said tissue comprises cartilage.
 59. The method of claim 52 wherein said soft tissue comprises cartilage.
 60. The method of claim 49 wherein said tissue is adjacent a hernia.
 61. An implantable tissue approximation device comprising: a) a biodegradable backing having two sides and at least one such side having i.) opposing first and second ends separated by a center area, ii.) first and second discrete contact areas respectively adjacent the first and second opposing ends, and iii.) a plurality of biodegradable attachment points extending from each of the first and second discrete contact areas only on one such side to attach to tissue adjacent the first and second discrete contact areas, wherein the plurality of biodegradable attachment points are configured to distribute tension between the respective first and second discrete contact areas and the adjacent tissue and, further, wherein the biodegradable backing has physical characteristics sufficient to approximate issue adjacent the first contact area with respect to the second contact area, and b) the plurality of biodegradable attachment points extending both from the first and second discrete contact areas wherein the plurality of attachment points have shapes and directions selected from the group consisting of canted tines, erect tines, canted hooks, canted arrowheads, erect barbed tipped tines, canted barbed tipped tines, erect arrowhead tipped tines, canted arrowhead tipped tines, erect nail-shaped tines, canted nail-shaped tines, and cheese grater-like tines.
 62. The tissue approximation device of claim 61 wherein a majority of said plurality of biodegradable attachment points are canted toward said center area.
 63. The tissue approximation device of claim 61 wherein said plurality of biodegradable attachment points are canted toward said center area.
 64. The tissue approximation device of claim 61 wherein said biodegradable backing and said plurality of biodegradable attachment points comprise at least one biodegradable material selected from the group consisting of polyglycolide, polylactide, poly-α-caprolactone, polyglyconate, polylactide-co-glycolide, their mixtures, alloys, and random and block copolymers. 